Systemd handles some power-related [http://en.wikipedia.org/wiki/Advanced_Configuration_and_Power_Interface ACPI] events. They can be configured via the following options from {{ic|/etc/systemd/logind.conf}}:

+

Systemd handles some power-related [[Wikipedia:Advanced_Configuration_and_Power_Interface|ACPI]] events. They can be configured via the following options from {{ic|/etc/systemd/logind.conf}}:

* {{ic|HandlePowerKey}}: specifies which action is invoked when the power key is pressed.

* {{ic|HandlePowerKey}}: specifies which action is invoked when the power key is pressed.

systemd is a system and service manager for Linux, compatible with SysV and LSB init scripts. systemd provides aggressive parallelization capabilities, uses socket and D-Bus activation for starting services, offers on-demand starting of daemons, keeps track of processes using Linux control groups, supports snapshotting and restoring of the system state, maintains mount and automount points and implements an elaborate transactional dependency-based service control logic. It can work as a drop-in replacement for sysvinit.

Note: For a detailed explanation as to why Arch has moved to systemd, see this forum post.

Things to consider before you switch

It is highly recommended to switch to the new initscripts configuration system described in the rc.conf article. Once you have this configuration established, you will have done most of the work needed to make the switch to systemd.

Systemd will start the daemons listed in /etc/rc.conf and run /etc/rc.local and /etc/rc.local.shutdown on boot/shutdown respectively (see #Initscripts emulation below). If the legacy support for DAEMONS in rc.conf or the scripts in rc.local is not needed, the corresponding service files can be masked to disable them.

If you were starting a login manager (SLiM, GDM, etc.) using /etc/inittab it will no longer start, because systemd doesn't use inittab. The wiki page for the login manager should tell you how to add it as a systemd service.

Warning: In case you have daemons in the DAEMONS array which have native systemd service files, the native service files will be used automatically. However, if the names of the rc script and the systemd service file do not match, this will not work and you should make sure that only one of the two (preferably the native one) is enabled.

Warning: Systemd is an asynchronous starting process, compared to the sequential DAEMONS startup. In particular, network being a legacy service, may start too late to enable interfaces which are required by other services. You are advised to move to netcfg or NetworkManager before embarking to systemd.

Mixed systemd/initscripts installation

It is possible to replace sysvinit with systemd, but keep initscripts around in case there are some rc scripts which do not yet have systemd equivalents (see #Initscripts emulation below).

Follow the instructions for a mixed systemd/sysvinit/initscripts installation.

Enable daemons formerly listed in /etc/rc.conf with systemctl enable daemonname. For a translation of the daemons from /etc/rc.conf to systemd services, see: List of Daemons and Services. Daemons that do not yet have equivalent systemd service files should be kept in the DAEMONS array so that systemd starts the legacy rc scripts.

Supplementary information

If you have quiet in your kernel parameters, you might want to remove it for your first couple of systemd boots, to assist with identifying any issues during boot.

Adding your user to groups (optical, audio, scanner, etc.) is not necessary for most use cases with systemd. The groups can even cause some functionality to break. For example, the audio group will break fast user switching and allows applications to block software mixing. Every PAM login provides a logind session, which for a local session will give you permissions via POSIX ACLs on audio/video devices, and allow certain operations like mounting removable storage via udisks.

Note: Systemd-logind replaced ConsoleKit, which was removed from the repositories, so a system must be booted with systemd to be fully functional. See here for more info.

Native configuration

Note: You may need to create these files. All files should have 644 permissions and root:root ownership.

Hostname

The hostname is configured in /etc/hostname. The file should not contain the system's domain, if any. To set the hostname, do:

# hostnamectl set-hostname myhostname

See man 5 hostname and man 1 hostnamectl for details.

Here is an example file:

/etc/hostname

myhostname

Locale

The default system locale is configured in /etc/locale.conf. To set the default locale, do:

# localectl set-locale LANG="de_DE.utf8"

Note: Before you set the default locale, you first need to enable locales available to the system by uncommenting them in /etc/locale.gen and then executing locale-gen as root. The locale set via localectl must be one of the uncommented locales in /etc/locale.gen.

Time zone

The time zone is configured by creating an appropriate /etc/localtime symlink, pointing to a zoneinfo file under /usr/share/zoneinfo/. To do this automatically:

# timedatectl set-timezone America/Toronto

See man 1 timedatectl and man 5 localtime for more details.

Alternatively, create the symlink yourself:

# ln -sf ../usr/share/zoneinfo/America/Toronto /etc/localtime

Hardware clock

Systemd will use UTC for the hardware clock by default.

Tip: It is advised to have a Network Time Protocol daemon running to keep the system time synchronized with Internet time and the hardware clock.

Hardware clock in localtime

If you want to change the hardware clock to use local time (STRONGLY DISCOURAGED) do:

# timedatectl set-local-rtc true

If you want to revert to the hardware clock being in UTC, do:

# timedatectl set-local-rtc false

Be warned that, if the hardware clock is set to localtime, dealing with daylight saving time is messy. If the DST changes when your computer is off, your clock will be wrong on next boot (there is a lot more to it). Recent kernels set the system time from the RTC directly on boot, assuming that the RTC is in UTC. This means that if the RTC is in local time, then the system time will first be set up wrongly and then corrected shortly afterwards on every boot. This is the root of certain weird bugs (time going backwards is rarely a good thing).

One reason for allowing the RTC to be in local time is to allow dual boot with Windows (which uses localtime). However, Windows is able to deal with the RTC being in UTC with a simple registry fix. There, it is recommended that Windows are changed to use UTC, rather than Linux to use localtime. If you make Windows use UTC, also remember to disable the "Internet Time Update" Windows feature, so that Windows don't mess with the hardware clock, trying to sync it with internet time. You should instead leave touching the RTC and syncing it to internet time to Linux, by enabling an NTP daemon, as suggested previously.

Kernel modules

Today, all necessary module loading is handled automatically by udev, so that, if you don't want/need to use any out-of-tree kernel modules, there is no need to put modules that should be loaded at boot in any config file. However, there are cases where you might want to load an extra module during the boot process, or blacklist another one for your computer to function properly.

Extra modules to load at boot

Extra kernel modules to be loaded during boot are configured as a static list in files under /etc/modules-load.d/. Each configuration file is named in the style of /etc/modules-load.d/<program>.conf. Configuration files simply contain a list of kernel module names to load, separated by newlines. Empty lines and lines whose first non-whitespace character is # or ; are ignored.

/etc/modules-load.d/virtio-net.conf

# Load virtio-net.ko at boot
virtio-net

See man 5 modules-load.d for more details.

Blacklisting

Filesystem mounts

The default setup will automatically fsck and mount filesystems before starting services that need them to be mounted. For example, systemd automatically makes sure that remote filesystem mounts like NFS or Samba are only started after the network has been set up. Therefore, local and remote filesystem mounts specified in /etc/fstab should work out of the box.

See man 5 systemd.mount for details.

Automount

If you have a large /home partition, it might be better to allow services that do not depend on /home to start while /home is being fsck'ed. This can be achieved by adding the following options to the /etc/fstab entry of your /home partition:

noauto,x-systemd.automount

This will fsck and mount /home when it is first accessed, and the kernel will buffer all file access to /home until it is ready.

The same applies to remote filesystem mounts. If you want them to be mounted only upon access, you will need to use the noauto,x-systemd.automount parameters. In addition, you can use the x-systemd.device-timeout=# option to specify a timeout in case the network resource is not available.

If you have encrypted filesystems with keyfiles, you can also add the noauto parameter to the corresponding entries in /etc/crypttab. Systemd will then not open the encrypted device on boot, but instead wait until it is actually accessed and then automatically open it with the specified keyfile before mounting it. This might save a few seconds on boot if you are using an encrypted RAID device for example, because systemd doesn't have to wait for the device to become available. For example:

/etc/crypttab

data /dev/md0 /root/key noauto

LVM

If you have LVM volumes not activated via the initramfs, enable lvm.service (provided by the lvm2 package):

# systemctl enable lvm

Similarly, if you have LVM on encrypted devices mounted later during boot (e.g. from /etc/crypttab), enable lvm-on-crypt.service (also provided by the lvm2 package):

# systemctl enable lvm-on-crypt

ACPI power management

Systemd handles some power-related ACPI events. They can be configured via the following options from /etc/systemd/logind.conf:

HandlePowerKey: specifies which action is invoked when the power key is pressed.

HandleSuspendKey: specifies which action is invoked when the suspend key is pressed.

HandleHibernateKey: specifies which action is invoked when the hibernate key is pressed.

HandleLidSwitch: specifies which action is invoked when the lid is closed.

The specified action can be one of ignore, poweroff, reboot, halt, suspend, hibernate or kexec.

If these options are not configured, systemd will use its defaults: HandlePowerKey=poweroff, HandleSuspendKey=suspend, HandleHibernateKey=hibernate, and HandleLidSwitch=suspend.

On systems which run no graphical setup or only a simple window manager like i3 or awesome, this may replace the acpid daemon which is usually used to react to these ACPI events.

In the current version of systemd, the Handle options will apply throughout the system unless they are "inhibited" (temporarily turned off) by a program, such as a power manager inside a desktop environment. If these inhibits are not taken, you can end up with a situation where systemd suspends your system, then when it wakes up the other power manager suspends it again.

Warning: Currently, the power manager in newest version of KDE is the only one that issues the necessary "inhibited" commands. Until the others do, you will need to set the Handle options to ignore if you want your ACPI events to be handled by GNOME, Xfce, acpid or other programs. New versions are on the way that will include this functionality.

Note: Systemd can also use other suspend backends (such as Uswsusp or TuxOnIce), in addition to the default kernel backend, in order to put the computer to sleep or hibernate.

Sleep hooks

Systemd does not use pm-utils to put the machine to sleep when using systemctl suspend or systemctl hibernate; pm-utils hooks, including any custom hooks, will not be run. However, systemd provides a similar mechanism to run custom scripts on these events. Systemd runs all executables in /usr/lib/systemd/system-sleep/, passing two arguments to each of them:

Argument 1: either pre or post, depending on whether the machine is going to sleep or waking up

Argument 2: either suspend or hibernate, depending on which is being invoked

In contrast to pm-utils, systemd will run these scripts concurrently and not one after another.

The output of any custom script will be logged by systemd-suspend.service or systemd-hibernate.service. You can see its output in systemd's journal:

# journalctl -b -u systemd-suspend

Note that you can also use sleep.target, suspend.target or hibernate.target to hook units into the sleep state logic instead of using custom scripts.

Temporary files

Systemd-tmpfiles uses configuration files in /usr/lib/tmpfiles.d/ and /etc/tmpfiles.d/ to describe the creation, cleaning and removal of volatile and temporary files and directories which usually reside in directories such as /run or /tmp. Each configuration file is named in the style of /etc/tmpfiles.d/<program>.conf. This will also override any files in /usr/lib/tmpfiles.d/ with the same name.

tmpfiles are usually provided together with service files to create directories which are expected to exist by certain daemons. For example the Samba daemon expects the directory /var/run/samba to exist and to have the correct permissions. The corresponding tmpfile looks like this:

/usr/lib/tmpfiles.d/samba.conf

D /var/run/samba 0755 root root

However, tmpfiles may also be used to write values into certain files on boot. For example, if you use /etc/rc.local to disable wakeup from USB devices with echo USBE > /proc/acpi/wakeup, you may use the following tmpfile instead:

/etc/tmpfiles.d/disable-usb-wake.conf

w /proc/acpi/wakeup - - - - USBE

The tmpfiles method is recommended in this case since systemd doesn't actually support /etc/rc.local.

See man 5 tmpfiles.d for details.

Units

A unit configuration file encodes information about a service, a socket, a device, a mount point, an automount point, a swap file or partition, a start-up target, a file system path or a timer controlled and supervised by systemd. The syntax is inspired by XDG Desktop Entry Specification .desktop files, which are in turn inspired by Microsoft Windows .ini files.

See man 5 systemd.unit for details.

Transitioning from initscripts to systemd

Initscripts emulation

Integration with Arch's classic configuration is provided by the initscripts package. When initscripts are installed in parallel with systemd, with the system running on systemd, systemd will do the following:

Parse the DAEMONS array of /etc/rc.conf and start all listed daemons at boot

Execute /etc/rc.local during boot

Execute /etc/rc.local.shutdown during shutdown

Initscripts emulation is simply meant as a transitional measure to ease users' move to systemd, and will eventually go away. Native systemd does not rely on rc.conf centralised configuration, so it is recommended to use native systemd configuration files, which will take precedence over /etc/rc.conf.

Note: The recommended way to replace /etc/rc.local is to write the custom service files for any things you want to run on the system startup. See the corresponding section.

Note: If you disabled Template:Keypress to reboot in /etc/inittab, you will have to reconfigure this setting for systemd by running systemctl mask ctrl-alt-del.target as root.

Moving away from the DAEMONS array

For a pure systemd setup, you should remove the /etc/rc.conf file entirely and enable services only via systemctl. For each <service_name> in the DAEMONS array in /etc/rc.conf, run:

# systemctl enable <service_name>

Tip: For a list of commonly used daemons with their initscripts and systemd equivalents, see this table.

If <service_name>.service does not exist:

Most probably, systemd uses a different name. For example, cronie.service replaces the crond init daemon; alsa-store.service and alsa-restore.service replace the alsa init daemon. Another important instance is the network daemon, which is replaced with another set of service files (see Configuring Network for more details.)

Otherwise, a service file may not be available for systemd. In that case, you'll need to keep rc.conf to start the service during boot up.

Tip: You may look inside a package that contains daemon start scripts for service names. For instance:

Finally, some services do not need to be explicitly enabled by the user. For instance, dbus.service will automatically be enabled when dbus-core is installed. alsa-store.service and alsa-restore.service are also enabled automatically by systemd. Check the list of available services and their state using the systemctl command like this: systemctl status <service_name>.

Basic systemctl usage

The main command used to introspect and control systemd is systemctl. Some of its uses are examining the system state and managing the system and services. See man 1 systemctl for more details.

Tip: You can use all of the following systemctl commands with the -H <user>@<host> switch to control a systemd instance on a remote machine. This will use SSH to connect to the remote systemd instance.

Note: systemadm is the official graphical frontend for systemctl. It is provided by the systemd-ui-gitAUR package from the AUR.

Analyzing the system state

List running units:

$ systemctl

or:

$ systemctl list-units

List failed units:

$ systemctl --failed

The available unit files can be seen in /usr/lib/systemd/system/ and /etc/systemd/system/ (the latter takes precedence). You can see list installed unit files by:

$ systemctl list-unit-files

Using units

When using systemctl, you generally have to specify the complete name of the unit file, including its suffix, for example sshd.socket. There are however a few shortforms when specifying the unit in the following systemctl commands:

If you don't specify the suffix, systemctl will assume .service. For example, netcfg and netcfg.service are treated equivalent.

Mount points will automatically be translated into the appropriate .mount unit. For example, specifying /home is equivalent to home.mount.

Similiar to mount points, devices are automatically translated into the appropriate .device unit, therefore specifying /dev/sda2 is equivalent to dev-sda2.device.

See man systemd.unit for details.

Activate a unit immediately:

# systemctl start <unit>

Deactivate a unit immediately:

# systemctl stop <unit>

Restart a unit:

# systemctl restart <unit>

Ask a unit to reload its configuration:

# systemctl reload <unit>

Show the status of a unit, including whether it is running or not:

$ systemctl status <unit>

Check whether a unit is already enabled or not:

$ systemctl is-enabled <unit>

Enable a unit to be started on bootup:

# systemctl enable <unit>

Note: If services do not have an Install section, it usually means they are called automatically by other services. But if you need to install them manually, use the following command, replacing foo with the name of the service.

Show the manual page associated with a unit (this has to be supported by the unit file):

$ systemctl help <unit>

Power management

If you are in a local systemd-logind user session and no other session is active, the following commands will work without root privileges. If not (for example, because another user is logged into a tty), systemd will automatically ask you for the root password.

Using systemd-logind

In order to check the status of your user session, you can use loginctl. All PolicyKit actions like suspending the system or mounting external drives will work out of the box.

$ loginctl show-session $XDG_SESSION_ID

Writing custom .service files

Handling dependencies

With systemd, dependencies can be resolved by designing the unit files correctly. The most typical case is that the unit A requires the unit B to be running before A is started. In that case add Requires=B and After=B to the [Unit] section of A. If the dependency is optional, add Wants=B and After=B instead. Note that Wants= and Requires= do not imply After=, meaning that if After= is not specified, the two units will be started in parallel.

Dependencies are typically placed on services and not on targets. For example, network.target is pulled in by whatever service configures your network interfaces, therefore ordering your custom unit after it is sufficient since network.target is started anyway.

Type

There are several different start-up types to consider when writing a custom service file. This is set with the Type= parameter in the [Service] section. See man systemd.service for a more detailed explanation.

Type=simple: systemd considers the service to be started up immediately. The process must not fork. Do not use this type if other services need to be ordered on this service, unless it is socket activated.

Type=forking: systemd considers the service started up once the process forks and the parent has exited. For classic daemons use this type unless you know that it is not necessary. You should specify PIDFile= as well so systemd can keep track of the main process.

Type=oneshot: This is useful for scripts that do a single job and then exit. You may want to set RemainAfterExit= as well so that systemd still considers the service as active after the process has exited.

Type=notify: Identical to Type=simple, but with the stipulation that the daemon will send a signal to systemd when it is ready. The reference implementation for this notification is provided by libsystemd-daemon.so.

Type=dbus: The service is considered ready when the specified BusName appears on DBus's system bus.

Replacing provided unit files

The unit files in /etc/systemd/system/ take precedence over the ones in /usr/lib/systemd/system/.
To make your own version of a unit (which will not be destroyed by an upgrade), copy the old unit file from /usr/lib/ to /etc/ and make your changes there. Alternatively you can use .include to parse an existing service file and then override or add new options. For example, if you simply want to add an additional dependency to a service file, you may use:

Tip: You can use systemd-delta to see which unit files have been overridden and what exactly has been changed.

Syntax highlighting for units within Vim

Syntax highlighting for systemd unit files within Vim can be enabled by installing vim-systemdAUR from the AUR.

Targets

Systemd uses targets which serve a similar purpose as runlevels but act a little different. Each target is named instead of numbered and is intended to serve a specific purpose with the possibility of having multiple ones active at the same time. Some targets are implemented by inheriting all of the services of another target and adding additional services to it. There are systemd targets that mimic the common SystemVinit runlevels so you can still switch targets using the familiar telinit RUNLEVEL command.

Get current targets

The following should be used under systemd instead of runlevel:

$ systemctl list-units --type=target

Create custom target

The runlevels that are assigned a specific purpose on vanilla Fedora installs; 0, 1, 3, 5, and 6; have a 1:1 mapping with a specific systemd target. Unfortunately, there is no good way to do the same for the user-defined runlevels like 2 and 4. If you make use of those it is suggested that you make a new named systemd target as /etc/systemd/system/<your target> that takes one of the existing runlevels as a base (you can look at /usr/lib/systemd/system/graphical.target as an example), make a directory /etc/systemd/system/<your target>.wants, and then symlink the additional services from /usr/lib/systemd/system/ that you wish to enable.

Targets table

SysV Runlevel

systemd Target

Notes

0

runlevel0.target, poweroff.target

Halt the system.

1, s, single

runlevel1.target, rescue.target

Single user mode.

2, 4

runlevel2.target, runlevel4.target, multi-user.target

User-defined/Site-specific runlevels. By default, identical to 3.

3

runlevel3.target, multi-user.target

Multi-user, non-graphical. Users can usually login via multiple consoles or via the network.

5

runlevel5.target, graphical.target

Multi-user, graphical. Usually has all the services of runlevel 3 plus a graphical login.

6

runlevel6.target, reboot.target

Reboot

emergency

emergency.target

Emergency shell

Change current target

In systemd targets are exposed via "target units". You can change them like this:

# systemctl isolate graphical.target

This will only change the current target, and has no effect on the next boot. This is equivalent to commands such as telinit 3 or telinit 5 in Sysvinit.

Change default target to boot into

The standard target is default.target, which is aliased by default to graphical.target (which roughly corresponds to the old runlevel 5). To change the default target at boot-time, append one of the following kernel parameters to your bootloader:

Tip: The .target extension can be left out.

systemd.unit=multi-user.target (which roughly corresponds to the old runlevel 3),

systemd.unit=rescue.target (which roughly corresponds to the old runlevel 1).

Alternatively, you may leave the bootloader alone and change default.target. This can be done using systemctl:

# systemctl enable multi-user.target

The effect of this command is outputted by systemctl; a symlink to the new default target is made at /etc/systemd/system/default.target. This works if, and only if:

[Install]
Alias=default.target

is in the target's configuration file. Currently, multi-user.target and graphical.target both have it.

Journal

Since version 38, systemd has its own logging system, the journal. Therefore, running a syslog daemon is no longer required. To read the log, use:

# journalctl

By default (when Storage= is set to auto in /etc/systemd/journald.conf), the journal writes to /var/log/journal/. If the directory /var/log/journal/ does not exist (e.g. if you or some program delete it), systemd will not create it automatically, but instead write its logs to /run/systemd/journal. This means that logs will be lost on reboot.

Filtering output

journalctl allows you to filter the output by specific fields.

Examples:

Show all messages by a specific executable:

# journalctl /usr/lib/systemd/systemd

Show all messages by a specific process:

# journalctl _PID=1

Show all messages by a specific unit:

# journalctl -u netcfg

See man journalctl and systemd.journal-fields for details.

Journal size limit

If the journal is persistent (non-volatile), its size limit is set to a default value of 10% of the size of the respective file system. E.g. with /var/log/journal located on a 50 GiB root partition this would lead to 5 GiB of journal data. The maximum size of the persistent journal can be controlled by SystemMaxUse in /etc/systemd/journald.conf, so to limit it for example to 50 MiB uncomment and edit the corresponding line to:

SystemMaxUse=50M

Refer to man journald.conf for more info.

Journald in conjunction with syslog

Compatibility with classic syslog implementations is provided via a socket /run/systemd/journal/syslog, to which all messages are forwarded. To make the syslog daemon work with the journal, it has to bind to this socket instead of /dev/log (official announcement). The syslog-ng package in the repositories automatically provides the necessary configuration.

# systemctl enable syslog-ng

Optimization

Analyzing the boot process

Using systemd-analyze

Systemd provides a tool called systemd-analyze that allows you to analyze your boot process so you can see which unit files are causing your boot process to slow down. You can then optimize your system accordingly. You have to install python2-dbus and python2-cairo to use it.

To see how much time was spent in kernelspace and userspace on boot, simply use:

$ systemd-analyze

Tip: To see how much time was spent in the initramfs, append the timestamp hook to your HOOKS array in /etc/mkinitcpio.conf and as root, rebuild your initramfs with mkinitcpio -p linux

To list the started unit files, sorted by the time each of them took to start up:

$ systemd-analyze blame

You can also create a SVG file which describes your boot process graphically, similiar to Bootchart:

$ systemd-analyze plot > plot.svg

Using bootchart

You could also use a version of bootchart to visualize the boot sequence. Since you are not able to put a second init into the kernel command line you won't be able to use any of the standard bootchart setups. However the bootchart2AUR package from AUR comes with an undocumented systemd service. After you've installed bootchart2 do:

Readahead

Systemd comes with its own readahead implementation, this should in principle improve boot time. However, depending on your kernel version and the type of your hard drive, your mileage may vary (i.e. it might be slower). To enable, do:

# systemctl enable systemd-readahead-collect systemd-readahead-replay

Remember that in order for the readahead to work its magic, you should reboot a couple of times.

Early start for services

One central feature of systemd is D-Bus and socket activation. This causes services to be started when they are first accessed and is generally a good thing. However, if you know that a service (like UPower) will always be started during boot, then the overall boot time might be reduced by starting it as early as possible. This can be achieved (if the service file is set up for it, which in most cases it is) by issuing:

# systemctl enable upower

This will cause systemd to start UPower as soon as possible, without causing races with the socket or D-Bus activation.

Less output during boot

Change verbose to quiet on the bootloader's kernel line. For some systems, particularly those with an SSD, the slow performance of the TTY is actually a bottleneck, and so less output means faster booting.

Shell shortcuts

Systemd daemon management requires a bit more text entry to accomplish tasks such as start, stopped, enabling, checking status, etc. The following functions can be added to one's ~/.bashrc file to help streamline interactions with systemd and to improve the overall experience.

Troubleshooting

Shutdown/reboot takes terribly long

If the shutdown process takes a very long time (or seems to freeze) most likely a service not exiting is to blame. Systemd waits some time for each service to exit before trying to kill it. To find out if you are affected, see this article.